Abstract: Methods and devices for molecular imprinting include a molecular imprinting synthesis and matching a physiological pH of a template utilized in the molecular imprinting synthesis to achieve molecular imprinting. Molecular imprinting can be achieved by matching the physiological pH of the template used in a molecular imprinting synthesis. Furthermore, electrostatic charges can be complementary matched to the template, by obtaining crystallographic data of a protein template. Particularly, positively and negatively charged amino acids can be counted and matched by an oppositely charged monomer. For hydrophobic amino acids, isoleucin, leucin, and valine amino acids are counted. Since not all hydrophobic amino acids are exposed, the hydrophobic amino acid and hydrophobic monomer ratio can be determined experimentally by varying ratios from 1:1 to 1:10.

Abstract: Methods and devices for molecular imprinting include a molecular imprinting synthesis and matching a physiological pH of a template utilized in the molecular imprinting synthesis to achieve molecular imprinting. Molecular imprinting can be achieved by matching the physiological pH of the template used in a molecular imprinting synthesis. Furthermore, electrostatic charges can be complementary matched to the template, by obtaining crystallographic data of a protein template. Particularly, positively and negatively charged amino acids can be counted and matched by an oppositely charged monomer. For hydrophobic amino acids, isoleucin, leucin, and valine amino acids are counted. Since not all hydrophobic amino acids are exposed, the hydrophobic amino acid and hydrophobic monomer ratio can be determined experimentally by varying ratios from 1:1 to 1:10.

Abstract: An apparatus, system, and method for magnetic separation of cells are disclosed. By combining inkjet printing technology and magnetic labeling of cells, accurate cell counts are obtained using an optical microscope. Mouse CD4+ lymphocytes are attached to micron sized magnetic beads and printed through a modified, commercial inkjet printer. The labeled cells are then attached to a glass slide covering a permanent magnet. Cell counts can be obtained by use of regular and inverted optical microscopes and imaging software. The magnetically-labeled beads are collected for evaluation on a modified polymer coupon that is placed in front of a permanent magnet and the unlabeled cells fall into an excess container. Flow cytometry results verify the presence of the CD4+ protein on the LBRM-33 lymphocytes membrane. Protein-specific attachment of magnetic microspheres to the lymphocytes is utilized for sorting CD4+ lymphocytes.

Abstract: An apparatus, system, and method for magnetic separation of cells are disclosed. By combining inkjet printing technology and magnetic labeling of cells, accurate cell counts are obtained using an optical microscope. Mouse CD4+ lymphocytes are attached to micron sized magnetic beads and printed through a modified, commercial inkjet printer. The labeled cells are then attached to a glass slide covering a permanent magnet. Cell counts can be obtained by use of regular and inverted optical microscopes and imaging software. The magnetically-labeled beads are collected for evaluation on a modified polymer coupon that is placed in front of a permanent magnet and the unlabeled cells fall into an excess container. Flow cytometry results verify the presence of the CD4+ protein on the LBRM-33 lymphocytes membrane. Protein-specific attachment of magnetic microspheres to the lymphocytes is utilized for sorting CD4+ lymphocytes.